Electron microscopic observations of the bronchial epithelium of dogs

This paper studies the problem of vision-based simultaneous localization and mapping (SLAM) in dynamic environments with multiple cameras. These cameras move independently and can be mounted on different platforms. All cameras work together to build a global map, including 3D positions of static background points and trajectories of moving foreground points. We introduce intercamera pose estimation and intercamera mapping to deal with dynamic objects in the localization and mapping process. To further enhance the system robustness, we maintain the position uncertainty of each map point. To facilitate intercamera operations, we cluster cameras into groups according to their view overlap, and manage the split and merge of camera groups in real time. Experimental results demonstrate that our system can work robustly in highly dynamic environments and produce more accurate results in static environments.

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StructSLAM: Visual SLAM With Building Structure Lines

Zhou

Zou

Pei

et al. 2015

IEEE Trans. Veh. Technol.

223

102

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We propose a novel 6 DoF visual SLAM method based on the structural regularity of man-made building environments. The idea is that we use the building structure lines as features for localization and mapping. Unlike other line features, the building structure lines encode the global orientation information that constrains the heading of the camera over time, eliminating the accumulated orientation errors and reducing the position drift in consequence. We extend the standard EKF visual SLAM method to adopt the building structure lines with a novel parametrization method that represents the structure lines in dominant directions. Experiments have been conducted in both synthetic and real-world scenes. The results show that, our method performs remarkably better than the existing methods in terms of position error and orientation error. In the test of indoor scenes of the public RAWSEEDS datasets, with the aid of wheel odometer, our method produces bounded position errors about 0.79 meter along a 967 meter path even though no loop closing algorithm is applied.

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Simultaneous video defogging and stereo reconstruction

Tan

et al. 2015

115

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Prevalence and Clinical Features of Chronic Pancreatitis in China

Wang

et al. 2009

113

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Dynamic Magnetometer Calibration and Alignment to Inertial Sensors by Kalman Filtering

Zou

Liu

et al. 2018

IEEE Trans. Contr. Syst. Technol.

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Automated 3D trajectory measuring of large numbers of moving particles

Wu¹,

Zhao²,

Zou³

et al. 2011

Opt. Express

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Complex dynamics of natural particle systems, such as insect swarms, bird flocks, fish schools, has attracted great attention of scientists for years. Measuring 3D trajectory of each individual in a group is vital for quantitative study of their dynamic properties, yet such empirical data is rare mainly due to the challenges of maintaining the identities of large numbers of individuals with similar visual features and frequent occlusions. We here present an automatic and efficient algorithm to track 3D motion trajectories of large numbers of moving particles using two video cameras. Our method solves this problem by formulating it as three linear assignment problems (LAP). For each video sequence, the first LAP obtains 2D tracks of moving targets and is able to maintain target identities in the presence of occlusions; the second one matches the visually similar targets across two views via a novel technique named maximum epipolar co-motion length (MECL), which is not only able to effectively reduce matching ambiguity but also further diminish the influence of frequent occlusions; the last one links 3D track segments into complete trajectories via computing a globally optimal assignment based on temporal and kinematic cues. Experiment results on simulated particle swarms with various particle densities validated the accuracy and robustness of the proposed method. As real-world case, our method successfully acquired 3D flight paths of fruit fly (Drosophila melanogaster) group comprising hundreds of freely flying individuals.

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Chinese expert consensus on gastroesophageal reflux disease in 2020

Xiao

Zhou

Hou

et al. 2021

J of Digest Diseases

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Study of visceral hypersensitivity in irritable bowel syndrome

Dong

Zou

et al. 2004

Chinese Journal of Digestive Diseases

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Danping Zou

CoSLAM: Collaborative Visual SLAM in Dynamic Environments

StructSLAM: Visual SLAM With Building Structure Lines

Simultaneous video defogging and stereo reconstruction

Prevalence and Clinical Features of Chronic Pancreatitis in China

Dynamic Magnetometer Calibration and Alignment to Inertial Sensors by Kalman Filtering

Automated 3D trajectory measuring of large numbers of moving particles

Chinese expert consensus on gastroesophageal reflux disease in 2020

Study of visceral hypersensitivity in irritable bowel syndrome

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